The role of storage technologies throughout the decarbonisation of the sector-coupled European energy system

Abstract

We use an open, hourly-resolved, networked model of the European energy system to investigate the storage requirements under decreasing CO2 emissions targets and several sector-coupling scenarios. For the power system, significant storage capacities only emerge for CO2 reductions higher than 80% of 1990 level in that sector. For 95% CO2 reductions, the optimal system includes electric batteries and hydrogen storage energy capacities equivalent to 1.4 and 19.4 times the average hourly electricity demand. Coupling heating and transport sectors enables deeper global CO2 reductions before the required storage capacities become significant, which highlights the importance of sector coupling strategies in the transition to low carbon energy systems. A binary selection of storage technologies is consistently found, i.e., electric batteries act as short-term storage to counterbalance solar photovoltaic generation while hydrogen storage smooths wind fluctuations. Flexibility from the electric vehicle batteries provided by coupling the transport sector avoid the need for additional stationary batteries and reduce the usage of pumped hydro storage. Coupling the heating sector brings to the system large capacities of thermal energy storage to compensate for the significant seasonal variation in heating demand.